Berlin 2015 – wissenschaftliches Programm
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TT: Fachverband Tiefe Temperaturen
TT 105: Quantum Information Systems: Si Vacancies and NV Centers (jointly with HL)
TT 105.2: Vortrag
Donnerstag, 19. März 2015, 15:15–15:30, ER 164
SiC nano-crystalline NIR emitters based on optically excited and spin polarized defects — •F. Fuchs1, A. Muzha2, N. Tarakina3,4, D. Simin1, M. Trupke5, P. Baranov6, V. Dyakonov1,3,7, A. Krueger2,3, and G. Astakhov1 — 1Exp. Physics VI, University of Würzburg — 2Institute of Organic Chemistry, University of Würzburg — 3Wilhelm Conrad Röntgen RCCM, University of Würzburg — 4Exp. Physics III, University of Würzburg — 5Vienna Center for Quantum Science and Technology, TU Wien — 6Ioffe Institute, St. Petersburg — 7ZAE Bayern, Würzburg
The unification of luminescent markers for bioimaging and spin centers for quantum sensing [1] is challenging; especially when aiming for the ideal NIR window, stability and non-toxicity. Bulk silicon carbide (SiC) is a favored candidate despite its large band gap, which we could mitigate by the introduction of silicon vacancy defects—exhibiting NIR emission—via neutron irradiation. With a milling procedure, we fabricated SiC nano crystals ranging from 600nm down to 60nm in size, with a further fragmentation of the latter into clusters of high crystalline quality (size ca. 10 nm) separated by amorphous material. The luminescence of the vacancies persists in all size fractions, moreover, we detected room-temperature spin resonance [2]. This leads to new perspectives: defects in nano crystalline SiC as in-vivo luminescent markers and simultaneously as magnetic field or temperature sensors [3].
[1] Riedel et al.: Phys. Rev. Lett. 109, 22 (2012)
[2] Fuchs et al. arXiv: 1409.0756v1
[3] Kraus et al.: Sci. Rep. 4, 5303 (2014)